Author
Listed:
- Zhaoliang Liao
(Oak Ridge National Laboratory)
- Elizabeth Skoropata
(Oak Ridge National Laboratory)
- J. W. Freeland
(Argonne National Laboratory)
- Er-Jia Guo
(Oak Ridge National Laboratory)
- Ryan Desautels
(Oak Ridge National Laboratory)
- Xiang Gao
(Oak Ridge National Laboratory)
- Changhee Sohn
(Oak Ridge National Laboratory)
- Ankur Rastogi
(Oak Ridge National Laboratory)
- T. Zac Ward
(Oak Ridge National Laboratory)
- Tao Zou
(Oak Ridge National Laboratory)
- Timothy Charlton
(Oak Ridge National Laboratory)
- Michael R. Fitzsimmons
(Oak Ridge National Laboratory
University of Tennessee)
- Ho Nyung Lee
(Oak Ridge National Laboratory)
Abstract
Artificial heterostructures composed of dissimilar transition metal oxides provide unprecedented opportunities to create remarkable physical phenomena. Here, we report a means to deliberately control the orbital polarization in LaNiO3 (LNO) through interfacing with SrCuO2 (SCO), which has an infinite-layer structure for CuO2. Dimensional control of SCO results in a planar-type (P–SCO) to chain-type (C–SCO) structure transition depending on the SCO thickness. This transition is exploited to induce either a NiO5 pyramidal or a NiO6 octahedral structure at the SCO/LNO interface. Consequently, a large change in the Ni d orbital occupation up to ~30% is achieved in P–SCO/LNO superlattices, whereas the Ni eg orbital splitting is negligible in C–SCO/LNO superlattices. The engineered oxygen coordination triggers a metal-to-insulator transition in SCO/LNO superlattices. Our results demonstrate that interfacial oxygen coordination engineering provides an effective means to manipulate the orbital configuration and associated physical properties, paving a pathway towards the advancement of oxide electronics.
Suggested Citation
Zhaoliang Liao & Elizabeth Skoropata & J. W. Freeland & Er-Jia Guo & Ryan Desautels & Xiang Gao & Changhee Sohn & Ankur Rastogi & T. Zac Ward & Tao Zou & Timothy Charlton & Michael R. Fitzsimmons & Ho, 2019.
"Large orbital polarization in nickelate-cuprate heterostructures by dimensional control of oxygen coordination,"
Nature Communications, Nature, vol. 10(1), pages 1-7, December.
Handle:
RePEc:nat:natcom:v:10:y:2019:i:1:d:10.1038_s41467-019-08472-y
DOI: 10.1038/s41467-019-08472-y
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